A conveying device for a linear transport system, wherein the conveying device comprises at least one rolling unit and a carrier unit, wherein the carrier unit is of U-shaped configuration and has an outer side and an inner side, wherein the inner side bounds a receiving space for receiving a running rail of the linear transport system, wherein the rolling unit is arranged in the receiving space in a manner spaced apart from the inner side, wherein the inner side and/or the outer side are/is substantially free from undercuts and/or corners and/or bumps, and/or wherein the inner side and/or the outer side are/is of substantially smooth configuration.

A straddle mount idler assembly for use with a crawler assembly of a crawler machine. The straddle mount idler assembly includes an idler wheel positioned between inboard and outboard arms of a crawler assembly, the idler wheel fixed both rotationally and axially to an idler shaft. The wheel and shaft are fixed rotationally via locking key and axially via segmented retaining plate and bolts. The axial coupling of the wheel and shaft allows for axial thrust to be controlled outboard the crawler frame for easier access and maintenance. A sealed thrust plate assembly with a dedicated lubrication port is mounted to each bearing block. A retainer nut threadably engages the idler shaft, allowing ready tightening of the retainer when the thrust plate experiences wear, and the retaining nut is fixed to the shaft via a locking bar. A set of integrated inspection ports enable inspection and measurement of the thrust plate without splitting crawler tracks.

A low-friction roller assembly is provided. The low-friction roller assembly is especially suitable for use in a refrigerator for reducing noise and reducing wobble and vibration. The low-friction roller assembly has a rotating element encased within a fluid and secured within a housing. An axle attached to the rotating element extends outside of the housing and is connected to a wheel via a keyed interlocking component. The wheel is attached to mount assembly in, for example, a refrigerator, which is attached to a movable drawer.

A roller assembly for a mobile cleaning system for cleaning a work surface can include a drive shaft, a sheath, a bushing, and a bushing shroud. The drive shaft can be rotatable about a drive axis, and the drive shaft can include a driven end and an opposite bushing end. The sheath can be supported by the drive shaft and the sheath can be rotatable with the drive shaft. The sheath can include a shell engageable with the work surface. The bushing can be located about the bushing end of the drive shaft. The bushing shroud can be connected to the bushing. The sheath and the drive shaft can be together rotatable with respect to the bushing and the bushing shroud, the bushing shroud can include an outer portion defining a first radius of curvature and a recessed portion connected to the outer portion.

The slide-out roller consists of an inner thermoplastic core and a semi-rigid over-molded urethane cover with the Inner core having two sets of radially spaced recessed channels formed in its outer surface. The over-molded cover wraps the outer surface of the inner core and fully impregnates the recessed channels, which allows the cover to interdigitate and structurally integrate with the inner core to prevent slippage and drift.

A running wheel (1, 2) for a crane (16), in particular gantry crane, comprising a shaft (3), a wheel rim (4) and a hub (5) connecting the shaft (3) to the wheel rim (4) for rotation therewith, at least one connection between the hub (5) and the shaft (3) and/or between the hub (5) and the wheel rim (4) having a press fit (6) and a first form fit established by a first stop surface (8), the first form fit blocking a relative movement of the hub (5) in relation to the shaft (3) or the wheel rim (4) in a first direction (17) running parallel to an axis of rotation (7) of the running wheel (1, 2), wherein the connection additionally has at least one second form fit established by a second stop surface (9), wherein the second form fit blocks the relative movement of the hub (5) in relation to the shaft (3) or the wheel rim (4) in a second direction (18) opposed to the first direction (17).

A cam follower assembly includes a ball bearing having an outer ring and an inner assembly which includes two or more segments. The inner assembly is disposed in the outer ring with a full complement of balls disposed therebetween. The outer ring and inner assembly each include a race having a gothic arch cross sectional configuration that causes the balls to roll on two portions of each race.

A bearing system for a rotating vertical shaft includes a first ball bearing, having a first pitch diameter and a first axial stiffness and a second ball bearing having a second pitch diameter and a second axial stiffness. The first ball bearing is a deep groove Conrad bearing. The second ball bearing is an angular contact bearing. The first and second ball bearings are coaxial, secured to one another and rotatable together. The first pitch diameter is at least 1.5 times greater than the second pitch diameter. The bearing system has an axial stiffness ratio defined by the first axial stiffness divided by the second axial stiffness. The axial stiffness ratio is based on an axial preload force applied to the second outer ring such that an operating torque of the bearing system is within a predetermined range at temperatures from minus 40 to positive 85 degrees Celsius.

A rotary milking platform (1) comprises a platform (3) having a circular carrier beam (7) secured to the underside of the platform (3). The carrier beam (7) is supported on a plurality of support elements (10), each of which comprise a freely rotatable roller (35) which is configured to rollably engage an under surface (38) of the carrier beam (7). Each support element (10) comprises an anchor plate (27) adjustably mounted on a corresponding ground engaging element (20) which is secured to the ground. A carrier plate (40) is carried on four guide bolts (50) extending upwardly from the anchor plate (27). Side members (41) extending downwardly from the carrier plate (40) rotatably carry the roller (35). Compression springs (59) acting between abutment washers (55) secured to the guide bolts (50) and the carrier plate (40) urge the carrier plate (40) against heads (53) of the guide bolts (50). The compression springs (59) accommodate downward and upward movement of the roller (35) in order to accommodate rising and falling of the under surface (38) of the beam (7). The compression springs (59) permit tilting movement of the roller (35) about a tilt axis (61) which extends in the direction of motion of the beam (7) in order to facilitate tilting of the roller (35) to follow any non-horizontality of the under surface (38) of the beam (7). The tilt axis is located just below a line of contact (67) of the roller (35) with the under surface (38) of the beam (7) to minimise lateral movement of the roller relative to the beam (7) as the roller (35) tilts about the tilt axis.

A method for producing a roller bearing may include threading a cam roller onto a bearing sleeve until the cam roller abuts a first axial flange of the bearing sleeve and inserting a counter holder into the bearing sleeve until the first axial flange of the bearing sleeve abuts a stop of the counter holder. The method may also include heating the bearing sleeve and forming an opposite second axial flange via inserting a forming punch into the bearing sleeve after heating the bearing sleeve. The second axial flange may be formed such that the cam roller is held in the bearing sleeve with radial play and axial play after the bearing sleeve cools down. The method may further include removing the forming punch and the counter holder from within the bearing sleeve.